<p>In this work, it was shown that a nanocomposite of multi-walled carbon nanotubes (MWCNTs) and polydimethylsiloxane (PDMS) is a versatile material that can convert both thermal and mechanical energy into electrical energy. The MWCNT/PDMS nanocomposite with a MWCNT concertation of 2&#xa0;mass% was chemically etched to expose the carbon nanotubes on the surface of the nanocomposite. This resulted in a significant reduction in contact resistance, an increase in electrical conductivity, and consequently, an improvement in thermoelectric properties. For the first time, the MWCNT/PDMS nanocomposite was thoroughly analyzed to characterize its thermoelectric and triboelectric properties. Electrical conductivity, specific heat, thermal diffusivity, and thermal conductivity were investigated as a function of temperature in a wide range from 298 to 373&#xa0;K. The optimized characteristics of the MWCNT/PDMS nanocomposite were achieved due to its relatively high electrical conductivity (22&#xa0;S&#xa0;cm<sup>−1</sup>) and low thermal conductivity (0.22&#xa0;W&#xa0;m<sup>−1</sup>&#xa0;K<sup>−1</sup>). The Seebeck coefficient and thermoelectric efficiency factor were found to increase with temperature, reaching the maximum values of 4.6&#xa0;μV&#xa0;K<sup>−1</sup> and 7.4·10<sup>−5</sup>, respectively. The MWCNT/PDMS nanocomposite was used as a negative friction layer in a triboelectric nanogenerator (TENG). This device operated in contact-disconection mode, generating an output voltage of 7&#xa0;V and a current of 113&#xa0;nA. During long-term testing, the TENG demonstrated exceptional stability and repeatability of its voltage response. It was shown that the MWCNT/PDMS-based TENG is suitable for harvesting mechanical energy from human body movements, such as finger tapping, foot tapping, and hammering. The developed MWCNT/PDMS nanocomposite shows great potential for use in flexible wearable sensors for self-powered temperature monitoring and motion detection.</p>

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Exploring the potential of multifunctional MWCNT/PDMS nanocomposites in thermal and mechanical energy harvesting

  • Viktoriia Talaniuk,
  • Krystian Mistewicz,
  • Anna Gawron,
  • Andrzej Marcinkowski,
  • Urszula Szeluga,
  • Hanna Myalska-Głowacka,
  • Kushal Ruthvik Kaja,
  • Sugato Hajra,
  • Hoe Joon Kim,
  • Marcin Godzierz

摘要

In this work, it was shown that a nanocomposite of multi-walled carbon nanotubes (MWCNTs) and polydimethylsiloxane (PDMS) is a versatile material that can convert both thermal and mechanical energy into electrical energy. The MWCNT/PDMS nanocomposite with a MWCNT concertation of 2 mass% was chemically etched to expose the carbon nanotubes on the surface of the nanocomposite. This resulted in a significant reduction in contact resistance, an increase in electrical conductivity, and consequently, an improvement in thermoelectric properties. For the first time, the MWCNT/PDMS nanocomposite was thoroughly analyzed to characterize its thermoelectric and triboelectric properties. Electrical conductivity, specific heat, thermal diffusivity, and thermal conductivity were investigated as a function of temperature in a wide range from 298 to 373 K. The optimized characteristics of the MWCNT/PDMS nanocomposite were achieved due to its relatively high electrical conductivity (22 S cm−1) and low thermal conductivity (0.22 W m−1 K−1). The Seebeck coefficient and thermoelectric efficiency factor were found to increase with temperature, reaching the maximum values of 4.6 μV K−1 and 7.4·10−5, respectively. The MWCNT/PDMS nanocomposite was used as a negative friction layer in a triboelectric nanogenerator (TENG). This device operated in contact-disconection mode, generating an output voltage of 7 V and a current of 113 nA. During long-term testing, the TENG demonstrated exceptional stability and repeatability of its voltage response. It was shown that the MWCNT/PDMS-based TENG is suitable for harvesting mechanical energy from human body movements, such as finger tapping, foot tapping, and hammering. The developed MWCNT/PDMS nanocomposite shows great potential for use in flexible wearable sensors for self-powered temperature monitoring and motion detection.